DE19916664A1 - X-ray image processing method, involves checking coincidence of matching sides of image markings and ratio of common areas to achieve greater clarity by forming final summation marking - Google Patents

Abstract

The method involves displaying articles in a through-illuminated object on a monitor and setting markings (M1-M3) around certain predetermined articles. Markings are automatically combined to form a new marking if at least two markings match, whereby the coincidence of the matching sides of the markings and the ratio of the common areas of the matching markings are checked by a function to achieve greater clarity by forming a final summation marking (MG) in the x-ray image on the monitor.

Description

The invention relates to a method for processing an x-ray image according to the preamble of claim 1.

To the viewer of an x-ray image the evaluation of x-rayed objects will facilitate the x-ray image based on different properties in the X-ray system examined independently. A software searches for certain, beforehand defined objects, such as firearms, stabbing weapons, explosives in the illuminated object.

Such a method is disclosed in the unpublished DE-198 55 250.5. Becomes a such an object is determined, the viewer is informed that the object in the must examine the illuminated object in more detail. This notification is made by marking of the object found on the monitor, for example by placing a circle, a frame or the like. Since these detected objects are not recognized as a whole, a mark is placed around each detected object, whereby the evaluation by it is difficult for the viewer to see them in multiple numbers on the monitor be made. With a processing time of approx. 6 seconds, this is of great disadvantage for the viewer.

The task now arises from this, a method for processing an X-ray image to show that the set markings are optimized to give the viewer the evaluation to facilitate an x-ray image.

The object is achieved by the features of patent claim 1.

The invention is based on the idea of having many visible markings with one another connect automatically so that only one mark on the monitor as the sum of the individual  Markings is shown, which gives the viewer a central marking for a quick and safe evaluation of the object in the object is given. The connecting the markings are made by a function stored in the X-ray system, the appropriate one Combines the markings and places an overall marking in the X-ray image. Just related markings are combined. The affiliation results the spatial proximity of two markings and their overlaps.

Advantageous designs are contained in the subclaims.

In this way, inserted markings can also be removed again, for example if the operator wants the markings to be displayed individually. Also the degree is Summary of the markings adjustable. This can be achieved that the Markings are shown unchanged or always summarized. Are also Intermediate gradations possible, with a maximum of 2, 3, 4, 5, etc. markings with each other be connected so that on the monitor two to three marks, etc. as Individual total markings can be made visible.

The invention will be explained in more detail using an exemplary embodiment with a drawing.

It shows:

. Figure 1 is a simplified illustrated X-ray system;

Fig. 2 is a block diagram representation of a computer system in the X-ray system;

Fig. 3 is a visual representation of the procedure for setting a common marking on the monitor;

Fig. 4 Another visual representation of the method for removing the common marking on the monitor.

In Fig. 1, an X-ray system with a conventional X-ray generator 1 and with a detector device 2 is shown in simplified form. An object 3 to be determined is located between the detector device 2 and the X-ray generator 1 . This object 3 can be a suitcase in which various objects 4 , 5 , 6 are arranged. A computer system 7 is connected to the detector device 2 via known components (not shown here). The measurement results are visualized via a display device, for example a monitor 8 or a printer 9 , which are connected to the computer system 7 .

In FIG. 2, the essential components of the computer system 7 are shown for the sequence of the method. The output of the detector device 2 (not shown in detail) is guided to an image processing device 10 , which is connected to a marker memory 11 and a memory 12 for marker lists. The marking memory 11 accesses the memory 12 bidirectionally and thus the marking list built up during the method. At the same time, the marker memory 11 has a submarker memory 11.1 (is still being executed).

The procedure is as follows.

X-ray radiation is brought from the x-ray generator 1 as an x-ray beam FX1 onto the object 3 to be examined. This x-ray radiation FX1 is attenuated by the respective absorption behavior of the objects 4 , 5 , 6 in the object 3 and by the housing material of the object 3 and is recorded by the detector device 2 . The detector device 2 , for example a line camera, consisting of a plurality of X-ray detectors, delivers signals from the non-absorbed X-rays, which are fed into the computer system 7 as image data information about the X-rayed object 3 for image processing. This feed is preferably carried out line by line and continuously. The image data are evaluated in a known manner in the image processing device 10 and processed for a monitor display, an X-ray image thus represented being composed of pixels with different properties, for example gray value and material value, from which the object 4 , 5 , 6 can be determined.

When dangerous defined objects 4 , 5 , 6 are detected, in principle a separate marking M1, M2, M3 is automatically placed around each of these objects 4 , 5 , 6 (cf. FIG. 3). In this case, the marking M1 is placed around the object 4 recognized first and a marking M2 is placed around the object 5 recognized as the second. The two markings M1, M2 are already compared with one another, the two markings M1 and M2 being judged by a function as to whether the two markings M1 and M2 match one another, for which purpose the sides of the marking M1 and the marking M2 that match or point to one another by means of coordinate comparison be compared. The larger these pages match in position and length, the better they fit together. The distance between the marking M1 and the marking M2 must not exceed a preset variable limit.

In the present exemplary embodiment, the markings M1 and M2 are too far apart, so that no common marking is set. Both markings M1 and M2 are written into the memory 12 and into the submarking memory 11.1 of the marking memory 11 .

The object 6 is detected and the marker M3 is placed around this object 6 at approximately the same time. In a further step, this marking M3 is compared with the marking M1, ie it is determined whether the two markings M1 and M3 match each other. Since the two markings M1 and M3 intersect in the matching sides, the ratio of the common (overlapping) area of both markings M1 and M3 (intersection) to the area of the smaller of the two markings M1 and M3 is determined in addition to the matching sides . The larger this ratio, the better the two markings M1 and M3 fit together. As shown in FIG. 3b, the markings M1 and M3 are replaced by a new marking as individual sum marking M1 / 3, the outer sides of the marking M1 and M3 respectively giving the size of the new individual sum marking M1 / 3. So that these markings M1 and M3 are not lost in the computer system, they are stored as submarkings M1 and M3 in the submarking memory 11.1 as submarkings M1 and M3 of the individual sum marking M1 / 3.

At approximately the same time, the new individual sum marking M1 / 3 is compared with the marking M2 from the marking list for agreement. As a result of this comparison, a new marker Mg is placed on the monitor 8 as a final total marker, the objects 4 , 5 , 6 being located under the final total marker Mg (cf. FIG. 3c). The marking M2 and the individual total marking M1 / 3 become submarkings of the final total marking Mg. For the viewer (not shown in more detail), this results in a clear x-ray image on the monitor 8 , on which only one final total marking Mg is advantageously displayed, without assignments between them the individual markings M1, M2, M3 and the representation on the monitor 8 of the total mark Mg are lost.

The information about the individual markings M1, M2, M3 and their assignment as submarkings with respect to the individual sum marking M1 / 3 and final sum marking Mg remain in the computer system 7 in the memory 12 and the submarking memory 11.1 . It is thus possible, when deleting the final total marking Mg, to display all sub-markings M1 and M3 belonging to this total of the individual total marking M1 / 3 and the sub-marking M2 again separately. For this purpose, the end total marking Mg is removed from the monitor 8 by the operator, for example, at the push of a button, whereby the computer system 7 makes the individually stored markings M1, M2 (M3 not shown here in greater detail) visible again on the monitor 8 (see FIGS. 4a to 4c). .

This necessary information is taken from the submarking memory 11.1 and the marking list in the memory 12 step by step. The computer system 7 processes the previously described steps backwards. First, it is determined which final total mark Mg has been removed and the submarker memory 11.1 is searched for the individual associated submarkers. The sub-marking M1 / 3 associated with the final total marking Mg and the sub-marking M2 are found. The final total marking Mg is deleted from the marking list and the submarking M1 / 3 found in the submarking memory 11.1 and the submarking M2 are entered in the marking list of the memory 12 . The software of the computer system 7 also recognizes that the submarking M1 / 3 as an individual sum marking is composed of further markings M1 and M3, while the submarking M2 has no further submarkings and thus represents a single marking. The individual sum marking M1 / 3 is deleted from the marking list and this is replaced by the submarkings M1 and M3, which are read into the memory 12 from the submarking memory 11.1 . The individual markings M1, M2 and M3 are given and displayed on the monitor 8 from the marking list. In this way, the operator can decide for himself whether he would like to have the common mark Mg or the sub-mint markings M1 / 3, M2 or only the individual markings M1, M2, M3 etc. displayed.

It goes without saying that when several objects are detected, ie more than these three objects 4 , 5 , 6 in this exemplary embodiment, the set markings M1, M2, M3 etc. are compared with one another until there are no matching markings (individual sum markings) were found.

Variants are, however, also possible within the framework of the inventive concept. So the degree the summary of the marking can be set. With this setting can be achieved that marks are not always or only partially summarized, d. H. there are intermediate gradations with regard to the degree of summarization are also possible. This allows individual markings can also be removed from combined markings, these being then disintegrate into several parts.  

Reference list

1

X-ray generator

2nd

Detector device

3rd

object

4th

object

5

object

6

object

7

Computer system

8th

monitor

9

printer

10th

Image processing device

11

Mark memory

11.1

Submarking memory

12th

Storage
M1- M3 markings / submarkings
M1 / 3 single total marking / submarking
Mg total mark

Claims (5)

1. A method for processing an x-ray image in which objects are made visible to an operator on a monitor in an illuminated object, with markings being placed around certain, previously defined objects, characterized in that markings (M1, M2, M3. .) can then be automatically combined step by step into a new marking (M) if at least two markings (M1, M2, M3...) match each other, with a function of matching the matching sides of the markings (M1, M2 , M3...) As well as the ratio of the common areas of the matching markings (M1, M2, M3...) Is checked, which creates greater clarity by forming a final total marking (Mg) within the x-ray image on the monitor ( 8 ). 2. The method according to claim 1, characterized in that the individual markings (M1, M2, M3...) Are buffered in a mark list of a memory ( 12 ),
the individual markings (M1, M2, M3...) are compared with one another, a new individual sum marking (M1 / 3) is created during the comparison, which is read into the marking list as a single sum marking (M1 / 3) and buffered,
the markings (M1, M3), which become submarkings (M1, M3) of the individual sum marking (M1 / 3), are read from the marking list and transferred to a submarking memory ( 11.1 ) of a marking memory ( 11 ), the individual sum marking generated ( M1 / 3) is compared with a further marker (M2...) From the marker list,
a final total marking (Mg) resulting from the comparison is entered in the marking list and
the sub-markings (M1 / 3, M2) of the final total marking (Mg) are stored in the submarking memory ( 11.1 ), the structures of the individual sub-markings (M1 / 3, M2, M1, M3...) being retained. 3. The method according to claim 2, characterized in that the degree of together version of the markings (M1, M2, M3...) can be set, which means instead of only one final total marker (Mg) several individual total markers (M1 / 3...) and / or individual markings (M1, M2, M3...) can be displayed. 4. The method according to any one of claims 1 to 3, characterized in that the structure of the individual markings (M1, M2, M3 ...) and the individual sum markings (M1 / 3) can be removed from the submarking memory ( 11.1 ), which again in the marking list can be entered if several markings (M1 / 3, M1, M2, M3...) are displayed instead of a total marker (Mg). 5. The method according to one or more of the preceding claims 1 to 4, characterized characterized that the comparison of the matching sides and surfaces of the Markings (M1 / 3, M1, M2, M3...) Are made by comparing the coordinates, in which the markings (M1 / 3, M1, M2, M3...) lie.